KR200146601Y1 - Connecting structure of deck panel and beam - Google Patents

Abstract

The present invention discloses a novel structure for coupling a deck panel to a beam.

Conventionally, the end of the deck panel is provided with a fixed bar and bonded to the beam to combine it, there is a problem that both deck panels are discontinuous and weak in strength and need to install a separate stud bolt for fixing the slab.

In this design, the inverted Ω-shaped stud bars are joined between the upper bars of the two deck panels and the beam so that the slab is integrally stopped on the beam without separate stud bolts and the two deck panels are continuous in strength.

Description

Deck Panel Beam Coupling Structure

1 is an exploded perspective view showing the structure of a conventional deck panel.

2 is a cross-sectional view of the bonded state after the concrete injection.

3 is a side view showing the structure and coupling structure of another conventional deck panel

4 and 5 are side views showing the coupling structure of the present invention.

* Explanation of symbols for main parts of the drawings

D: Deck panel B1, B2: Upper and lower reinforcing bars

L: Lattice P: Finishing Plate

I: stud bar 2: fixed part

3: extension part 4: connection part

H: beam F: flange (of beam)

The present invention relates to the construction of reinforced concrete slabs, and more particularly, to a structure in which a deck panel is coupled to a main structure such as a beam.

Reinforced concrete structure is a composite structure that uses a combination of concrete as a compression material and rebar as a tension material, and constitutes the predominance of general building structures.

The most common method for constructing such reinforced concrete structures is to construct formwork to form the outer surface of concrete, reinforce the reinforcement on the formwork, and inject concrete to form the mold when the curing is completed. It takes place to remove it.

Such formwork is generally hypothesized of plywood and lumber, etc. Since the work such as reinforcement of the reinforcement on the formwork should be performed, a considerable strength must be angulated. Therefore, the construction of the formwork itself is a kind of construction work for the furniture structure, and the removal of the formwork after curing of concrete also becomes the structure dismantling work, which requires considerable air.

In particular, the concrete surface and the formwork is easy to be attached, there is a lot of difficulty in dismantling, accordingly, the surface of the structure is poor to require a separate finishing work, and the formwork with weak durability is damaged, generating a large amount of waste materials after the completion of the construction.

The problem of using formwork has been improved in two directions. One solution is to improve the formwork itself, and to improve the easy construction or dismantling, the beautiful surface formation without the finishing work, and the repeated use due to the large durability.

In addition, the scheme is to use the formwork without the formwork, that is, the structure used to form the outer surface of the concrete as part of the reinforced concrete structure.

In such a formless process, a deck plate having a large corrugate cross section has been conventionally used. Deck plate has great bending and shear stiffness, so that workers can work on it only by straddling between beams or pillars, and it becomes part of the finishing material of the slab, so disassembly is unnecessary and wiring and There are a number of advantages to installing pipes in a bend.

However, in order to prevent corrosion of the deck plate, painting must be done on the exposed surface, and it is difficult to settle on the surface of the deck plate. In addition, the thickness of the slab is also increased to have a problem of lowering the layer height.

Proposed to solve the problem of such a deck plate is a deck panel as shown in FIG. Shown is a deck panel disclosed in Utility Model Publication No. 93-3882, etc., such a deck panel is a lattice material (L) that is bent in a zigzag form between the upper and lower reinforcing bars B1 and B2. To form a girder (G), and the girder (G) is formed on the finishing plate (P) by a spacer material (S) that is bent in a mountain shape to intersect the girder (G). It is configured to be fixed by spacing of.

Here, the finishing plate (P) is made of a material that does not require a separate anticorrosive coating, such as a plated steel sheet and is generally configured in the form of a corrugated plate for increasing the local strength.

The deck panel (D ') is composed of a span between the beams or pillars and supported on them, and then casts concrete from the top to form a slab as shown in FIG.

In the finished slab, the upper and lower reinforcing bars (B1, B2) constitute the main reinforcing bar of the slab, and the finishing plate (P) closes the lower surface of the slab. The upper part of the deck panel is provided with a mesh reinforcing bar (M) as necessary to reinforce the local strength of the slab, and it is also possible to add the main reinforcing bar.

The deck panel (D ') is connected over a beam such as an I beam or an H beam to form a continuous deck, and thus becomes a work platform for construction. Reinforced concrete slab will be constructed integrally with C).

On the other hand, the deck panel (D ') that spans the main structure, such as beams should be properly fixed to the beam, conventionally, for example, a coupling structure as shown in FIG. This structure is disclosed in Utility Model Publication No. 93-38882.

In FIG. 3, the two deck panels D spanning the upper flange of the beam H, such as the H beam or the I beam, are provided between the upper and lower reinforcing bars B1 and B2, respectively, and have a fixed span 10 extending downward. The lower portion of the fixed section 10 is welded to the flange (F) of the beam (B), the deck panel (D) is fixedly coupled to the beam (H).

Then, the reinforcing bar (M) is placed on top of the concrete is poured, as can be seen in the drawings, both deck panels (D) is not only continuous with each other, but a significant space is formed therebetween.

After the injection and curing of the concrete is completed, the completed slab acts as a flange of the beam (h) in strength. At this time, the slab and the beam (H) are integrally behaved by the space formed between the two deck panels (D). It becomes impossible.

Accordingly, in order to allow the slab to be fixed to the beam H, a plurality of stud pins 20 should be bonded to the top surface of the beam H in one or two rows or more. It takes devices and consumes a lot of air and cost.

In addition, since the girder (G) of the deck panel (D) on both sides of the beam (H) is not continuous with each other and is independent in strength, the coupling structure shown in FIG. 3 is locally loaded due to the movement of the equipment during construction or uniformity of concrete casting. If not, local deformation occurs, and the temporary structure itself of the upper and lower deck panels D may collapse.

In view of such conventional problems, an object of the present invention is to provide a coupling structure capable of continuously connecting a deck panel as well as fixing a beam and a slab without a separate stud bolt.

In order to achieve the above object, the coupling structure according to the present invention is a deck panel joined to the upper surface of the flange of the beam, an extension portion extending upward from both sides of the fixing portion, and horizontally extending from the end of both extensions of the deck panel It is characterized by having a stud bar (stud bar) configured in the form of approximately Ω having a connection portion joined to the upper reinforcing bar.

According to such a configuration, the stud bar integrally couples both deck panels and simultaneously fixes the beam and the slab.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 and 5, the stud bar 1 used in the coupling structure of the present invention is composed of reinforcing bars, preferably, deformed reinforcing bars or steel bars, and the upper flange of the beam H ( F) A fixing portion 2 joined to the upper surface, two extension portions 3 extending upwardly from both ends of the fixing portion 2, and horizontally extending from the ends of each of the extension portions 3 to each dead panel ( It is composed of a substantially inverted Ω type or hat shape with a connecting portion 4 joined to the upper reinforcement B1 of D).

Here, the deck panel (D) is composed of a plurality of girder (G) consisting of upper and lower reinforcement (B1, B2) connected by a lattice material (L) bonded to the finishing plate (P) a plurality of predetermined unit size.

Meanwhile, the angle formed by the extension part 3 with the horizontal plane may be configured as 90 ° as shown in FIG. 4, but as shown in FIG. 5 in order to fix the slab formed by the concrete pouring on the beam H. Likewise, it is desirable to have an angle of 90 ° or less.

Therefore, it is appropriate that the angle θ of the extension 3 is in the range of approximately 45 ° ≦ θ ≦ 90 °.

The process of installing the deck panel (D) by the present invention coupling structure is as follows.

First, the frame and formwork of the slab are formed on the both sides of the flange (F) of the beam (H) across the finishing plate (P) of the required number of deck panels (D). It also serves as a platform for the operator's work.

Next, both side soft parts 4 of the stud bar 1 are sequentially joined to the upper bars B1 of both deck panels D to connect the two deck panels D, and then the height of the stud bar 1 is increased. The stationary part 2 is fixed to the upper surface of the flange F of the beam H by fixing.

Here, both deck panels (D) are difficult to be installed coaxially correctly in construction, but the stud bar (1) is connected to both first and then the stud bar (1) to the beam (H) to compensate for some construction errors It becomes possible.

Next, between the upper or lower reinforcement (B1) or lower reinforcement (B2) of the two deck panels (D) by connecting reinforcing bars (not shown), or as shown in the reinforcement of the slab to complete the frame of the slab.

And when the concrete is injected and cured, the slab is completed. In this state, the bottom plate of the slab is finished with the closing plate (P) of the deck panel (D), the slab completed by the extension portion 3 of the stud bar (1) is integrally fixed to the beam (H) to the external force It behaves with the beam H relative to.

As described above, according to the present invention, the deck panel D may be integrally fixed to the beam H at both sides of the beam H, and the slab constructed without the separate stud pin 20 may be attached to the beam H. It can be fixed integrally.

Accordingly, the present invention has the effect of greatly reducing the airborne and city park value of reinforced concrete slab construction using the deck panel and provide a high-quality high-strength slab structure.

Claims (4)

In the structure for joining the deck panel across both sides of the upper surface of the flange of the beam, the fixing portion (2) bonded to the upper surface of the flange (F) of the beam (H), and extending upward from both ends of the fixing portion (2) Stud bar (1) having two extension portions (3) and two connecting portions (4) extending horizontally from the ends of each of the extension portions (3) and joined to the upper reinforcement (B1) of each of the deck panels (D) Beam coupling structure of the deck panel comprising a). The beam coupling structure of the deck panel according to claim 1, wherein an angle between the extension part 3 of the stud bar 1 and the horizontal plane is 45 ° to 90 °. The method according to claim 1, wherein the two deck panels (D) span the beam (H), and then the connecting portion (4) of the stud bar (1) to the upper reinforcement (B1) of the two deck panels (D). And joining the fixing part (2) of the stud bar (1) to the upper surface of the flange (F) of the beam (H). The beam coupling structure of claim 1, wherein reinforcing bars (M) are installed on two deck panels (D) connected by the stud bars (1).